EP1491511A1 - Anti-PMD system for optical fibres - Google Patents
Anti-PMD system for optical fibres Download PDFInfo
- Publication number
- EP1491511A1 EP1491511A1 EP04291420A EP04291420A EP1491511A1 EP 1491511 A1 EP1491511 A1 EP 1491511A1 EP 04291420 A EP04291420 A EP 04291420A EP 04291420 A EP04291420 A EP 04291420A EP 1491511 A1 EP1491511 A1 EP 1491511A1
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- EP
- European Patent Office
- Prior art keywords
- pmd
- optical fiber
- pulley
- translation
- rotation
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
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- 230000003287 optical effect Effects 0.000 title description 3
- 239000013307 optical fiber Substances 0.000 claims abstract description 159
- 238000011144 upstream manufacturing Methods 0.000 claims description 28
- 238000012681 fiber drawing Methods 0.000 claims description 27
- 230000033001 locomotion Effects 0.000 claims description 24
- 238000000576 coating method Methods 0.000 claims description 10
- 239000011248 coating agent Substances 0.000 claims description 9
- 239000000835 fiber Substances 0.000 claims description 7
- 230000007423 decrease Effects 0.000 claims description 3
- 238000006073 displacement reaction Methods 0.000 claims description 2
- 239000006185 dispersion Substances 0.000 abstract description 4
- 230000010355 oscillation Effects 0.000 description 6
- 239000011521 glass Substances 0.000 description 5
- 230000006835 compression Effects 0.000 description 3
- 238000007906 compression Methods 0.000 description 3
- 238000000034 method Methods 0.000 description 3
- 230000010287 polarization Effects 0.000 description 3
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- 230000002093 peripheral effect Effects 0.000 description 2
- 230000001902 propagating effect Effects 0.000 description 2
- 230000005540 biological transmission Effects 0.000 description 1
- 238000004140 cleaning Methods 0.000 description 1
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Images
Classifications
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- C—CHEMISTRY; METALLURGY
- C03—GLASS; MINERAL OR SLAG WOOL
- C03B—MANUFACTURE, SHAPING, OR SUPPLEMENTARY PROCESSES
- C03B37/00—Manufacture or treatment of flakes, fibres, or filaments from softened glass, minerals, or slags
- C03B37/01—Manufacture of glass fibres or filaments
- C03B37/02—Manufacture of glass fibres or filaments by drawing or extruding, e.g. direct drawing of molten glass from nozzles; Cooling fins therefor
- C03B37/03—Drawing means, e.g. drawing drums ; Traction or tensioning devices
- C03B37/032—Drawing means, e.g. drawing drums ; Traction or tensioning devices for glass optical fibres
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- C—CHEMISTRY; METALLURGY
- C03—GLASS; MINERAL OR SLAG WOOL
- C03B—MANUFACTURE, SHAPING, OR SUPPLEMENTARY PROCESSES
- C03B2203/00—Fibre product details, e.g. structure, shape
- C03B2203/10—Internal structure or shape details
- C03B2203/18—Axial perturbations, e.g. in refractive index or composition
- C03B2203/19—Alternating positive/negative spins or twists
-
- C—CHEMISTRY; METALLURGY
- C03—GLASS; MINERAL OR SLAG WOOL
- C03B—MANUFACTURE, SHAPING, OR SUPPLEMENTARY PROCESSES
- C03B2203/00—Fibre product details, e.g. structure, shape
- C03B2203/36—Dispersion modified fibres, e.g. wavelength or polarisation shifted, flattened or compensating fibres (DSF, DFF, DCF)
-
- C—CHEMISTRY; METALLURGY
- C03—GLASS; MINERAL OR SLAG WOOL
- C03B—MANUFACTURE, SHAPING, OR SUPPLEMENTARY PROCESSES
- C03B2205/00—Fibre drawing or extruding details
- C03B2205/06—Rotating the fibre fibre about its longitudinal axis
Definitions
- the invention relates to the field of anti-PMD systems whose purpose is to reduce the PMD of an optical fiber during the fiber drawing process.
- PMD is polarization modal dispersion ("polarization modal dispersion" in English terminology).
- the polarization mode dispersion is a disadvantage for the optical fiber because it causes a degradation of the signal propagating in the optical fiber. This disadvantage becomes more and more important as the rates in fiber optic communication networks increase.
- SZ system an anti-PMD system
- This system is based on the use of a rotating oscillating pulley.
- This oscillating pulley is an anti-PMD pulley.
- This system is for example described in the European Patent EP 582405 incorporated herein by reference, or in European Patent EP 744636.
- the SZ system is positioned at the base of the fiberizing tower, in the plane of passage of the optical fiber which Optical fiber makes an elbow at the anti-PMD pulley.
- the plane of passage of the optical fiber is also called fiber drawing plan.
- the pulley in rotation about its axis of rotation, also oscillates around the vertical fibering axis, which axis is its axis of oscillation, and symmetrically with respect to the fiber drawing plane.
- V-pulley located before the oscillating pulley and guide fingers located after the oscillating pulley are used to guide the optical fiber in the fiber drawing plane.
- the axis of the V-shaped pulleys is stationary.
- the assembly constituted by the guide fingers is generally immobile, that is to say that the assembly constituted by the guide fingers is neither in translation movement nor in rotational movement, nor in motion which would be a combination of translation and rotation.
- V-pulleys also have no translational movement.
- Oscillations of the oscillating pulley alternately from right to left then from left to right, apply a torsion torque on the optical fiber which is already covered with its secondary coating.
- a disadvantage of this prior art is to result in optical fibers whose PMD is still too high because rotations of the optical fiber on the surface of the oscillating pulley that are insufficiently controlled.
- the position of the optical fiber which rolls on the surface of the oscillating pulley is no longer controlled because the inertia of the optical fiber tends to keep it in the center of the pulley, instead of maintaining it in the fiber plane so as to increase the angle between the plane of the oscillating pulley and the plane of the fiber up to the desired value.
- This tendency to remain in place may cause the optical fiber to slide on the surface of the oscillating pulley instead of rolling on, at the ends of the oscillating pulley oscillations stroke.
- a third prior art it is known to use two anti-PMD pulleys to wedge the optical fiber between them and to impose the angle between the pulley planes and the fiber drawing plane, for example two pulleys that are movable in translation relative to one another. to the other as in the US2002 / 0026813 US patent application, or two oscillating pulley.
- This third prior art allows adequate control of the rotation of the optical fiber at fiber drawing speeds moderate but at the cost of additional inconveniences.
- Said guiding problems result in a reduction in the contact time between the optical fiber and the anti-PMD pulleys, hence a reduction in the rotation efficiency of the optical fiber on the anti-PMD pulleys, hence a reduction in the torque of torsion applied on the optical fiber by the anti-PMD pulleys, and therefore a too high PMD value on the final optical fiber, that is to say at the end of fiber drawing.
- the problems of variation of optical fiber diameter are very poorly managed by this kind of system compressing the optical fiber between two anti-PMD pulleys, because when the diameter of the optical fiber varies, the compression force is always either too high or far too weak
- the invention proposes an improved anti-PMD system, allowing at the same time a good control of the rotation of the optical fiber on the anti-PMD pulley obtained by a better guiding of the optical fiber at its angular offset with respect to the anti-PMD pulley plane, a good quality of optical fiber coating obtained by the absence of excessive compression of the optical fiber, the anti-PMD system being moreover relatively simple and robust.
- the anti-PMD pulley has a fixed axis of rotation and a single degree of freedom around this axis which is a degree of freedom in rotation about this axis, while at least one of the guiding devices is movable in translation so as to be able to vary the angle between the fiber drawing plane and the plane of the anti-PMD pulley by controlling the effective rotation of the optical fiber on the surface of the anti-PMD pulley.
- the rotation of the optical fiber on the surface of the anti-PMD pulley is thus controlled and controlled because the element responsible for the variation of the angle between the fiber plane and the plane of Anti-PMD pulley is a guide element which therefore better controls the angular offset between the plane of the anti-PMD pulley and the fibering plane of the optical fiber.
- the element responsible for the variation of the angle between the fiber plane and the plane of Anti-PMD pulley is a guide element which therefore better controls the angular offset between the plane of the anti-PMD pulley and the fibering plane of the optical fiber.
- the use of a single anti-PMD pulley avoids all the compression problems of the optical fiber of the third prior art, while the reduction of the degrees of freedom of the anti-PMD pulley leads to an increased simplification and robustness of the system.
- the torsion torque which is expressed in revolutions per meter of optical fiber, applied to the optical fiber is independent of the fiber drawing speed.
- the average rotation speed of the optical fiber is constant regardless of the fiber drawing speed.
- the rotation profile that is to say the spatial distribution and the direction of rotation along the optical fiber, will evolve. While for a pulley system in translation as in the second prior art, the average speed of rotation decreases with the fiber drawing speed, and the rotation profile also varies with the fiber drawing speed.
- an anti-PMD system comprising, an anti-PMD pulley on which an optical fiber is intended to roll and which is rotatable about an axis of rotation, at least two optical fiber guiding devices. located on either side of the anti-PMD pulley, characterized in that the axis of rotation of the anti-PMD pulley is fixed, in that the only degree of freedom of the anti-PMD pulley is the rotation around it of the axis of rotation of the anti-PMD pulley, and in that at least one of the guiding devices is movable in translation in a non-orthogonal direction of translation to the axis of rotation of the anti-PMD pulley.
- an anti-PMD system is preferably provided in which, during the fiber-optic fiberization, the movable guiding device translation shifts the optical fiber angularly relative to a plane perpendicular to the axis of rotation of the anti-PMD pulley, and the anti-PMD pulley applies, alternately in the direction of clockwise and in the opposite direction to that clockwise, a torsion torque to the optical fiber so as to reduce its PMD.
- the various stages of fabrication of the optical fiber during the fiber drawing process have an important influence on the ovality of the index and geometry of the core of the preform and consequently also of the optical fiber, which ovalities are one of the causes of a significant PMD.
- optical fibers whose PMD is too large can not be sold because said PMD degrade too much the optical signal transmitted by said optical fiber.
- the method used to reduce the PMD of an optical fiber consists of rotating the optical fiber on itself, alternatively in a direction of rotation, for example clockwise, and then in the direction of rotation. other, for example the opposite direction to that of the needles of a watch.
- the anti-PMD system which makes it possible to twist the optical fiber, located at the base of the fiberizing tower, preferably acts on the optical fiber covered with its two coatings.
- the torsion torque, applied to the optical fiber is transmitted to the viscous glass cone of the preform, located in the fiberizing furnace, several meters above the anti-PMD system.
- the "soft" and twisted glass that is pulled down from the fiber-drawing tower by pulling the capstan, then cools rapidly (this is called “glass tempering"), which freezes glass, the twist exerted by the anti-PMD system.
- glass tempering freezes glass
- the PMD linked to the index ovality (ovality of the index of the core in the plane perpendicular to the light transmission axis) can be corrected by the torsion of the optical fiber, as for the geometric ovality.
- a PMD which is linked to a defect in the glass, or to a variation of index along the longitudinal axis of the optical fiber, would not be modified by the anti-PMD system.
- FIG. 1 schematically represents a preferred example of an anti-PMD system according to the invention.
- the arrow sd shows the upstream-downstream direction of travel of the optical fiber 4 during fiber drawing.
- An anti-PMD pulley 1 is rotatable about an axis of rotation.
- the plane PP perpendicular to the axis ar is the plane of the pulley 1 anti-PMD.
- the peripheral surface 10 of the anti-PMD pulley 1 is the surface on which the optical fiber 4 is intended to roll.
- the anti-PMD pulley 1 has a radius R. On either side of the anti-PMD pulley 1, devices 2 and 3 for guiding are located.
- Upstream of the anti-PMD pulley 1 is the upstream guiding device 2.
- the upstream guiding device 2 is movable in translation in a translation direction represented by the arrows dt.
- the upstream guiding device 2 comprises two guiding fingers 21 and 22 between which the optical fiber 4 passes. In order not to damage the quality of the coating of the optical fiber 4, the two guiding fingers 21 and 22 are rotatable respectively around the axes 23 and 24.
- the direction of travel of the optical fiber 4 is represented by the arrow dd 1.
- downstream guiding device 3 Downstream of the anti-PMD pulley 1 is the downstream guiding device 3.
- the downstream guiding device 3 is movable in translation in a translation direction represented by the arrows dt.
- the downstream guiding device 3 comprises two guiding fingers 31 and 32 between which the optical fiber 4 passes. In order not to damage the quality of the coating of the optical fiber 4, the two guiding fingers 31 and 32 are rotatable respectively around axes 33 and 34.
- the running direction of the optical fiber 4 is represented by the arrow dd2.
- the fibering plane PF is the plane formed by the directions dd1 and dd2.
- the ar axis of rotation of the anti-PMD pulley 1 is fixed, that is to say that it is fixed relative to the entire anti-PMD system which itself is fixed relative to the tower at the bottom of which is the anti-PMD system.
- the axis ar is fixed in contrast to the prior art oscillating pulley, where the axis of rotation was movable so as to be able to oscillate.
- the only degree of freedom of the anti-PMD pulley 1 is the rotation about the axis of rotation of the anti-PMD pulley 1.
- the anti-PMD pulley 1 has no other degree of freedom in a reference system with respect to the entire anti-PMD system and therefore compared to the fiberizing tower, among the six traditional degrees of freedom, namely three degrees of freedom in rotation and three degrees of freedom in translation, the pulley 1 anti-PMD has only one degree of freedom which is a degree of freedom in rotation about the axis ar.
- the pulley 1 anti-PMD has in particular no degree of freedom in translation.
- At least one of the guiding devices 2 or 3 is movable in translation in a translation direction dt which is non-orthogonal to the axis of rotation of the anti-PMD pulley 1.
- the translation direction dt of the translationally movable guide device 2 or 3 is located in a plane parallel to both the axis of rotation of the anti-PMD pulley 1 and respectively to the direction of movement dd1 or dd2 of the optical fiber respectively at said guide device 2 or 3 during fiber drawing of the optical fiber, according to the guide device which is movable in translation.
- the guide device which is movable in translation.
- the translation direction dt is parallel to the rotation axis ar of the anti-PMD pulley 1.
- the guiding device 2 or 3 which is movable in translation, moves in translation in the direction dt of translation, alternately in the direction s1 then in the direction s2, the ends of its race being advantageously located on either side the equilibrium position of the optical fiber 4, preferably equidistant from said equilibrium position of the optical fiber 4 which equilibrium position corresponds to the vertical of the fiberizing tower.
- the optical fiber 4 is represented at its equilibrium position.
- the guiding device movable in translation angularly shifts the optical fiber 4 with respect to a plane perpendicular to the axis of rotation of the anti-PMD pulley 1, this perpendicular plane being the plane PP of the pulley 1 anti-PMD. Due to this angular offset, and through the speed of travel of the optical fiber 4 at the level of the anti-PMD pulley 1, said anti-PMD pulley 1 applies, via the contact between the optical fiber 4 and the surface 10 of the anti-PMD pulley 1, alternately clockwise and counterclockwise, a torsion torque to the optical fiber 4 so as to decrease the PMD of optical fiber 4.
- the torsion profile printed in the optical fiber 4 is a sinusoidal torsion profile.
- a triangular torsion profile is better than a sinusoidal torsion profile, especially for standard single-mode optical fibers and chromatic dispersion-compensated optical fibers.
- a substantially niche control is required to print a triangular torsion profile in the optical fiber.
- the translational movement of the movable guide device in translation is much slower at the ends of the race of said movement than in the middle of the course of said movement so as to print in the optical fiber during the drawing rather a triangular torsion profile than a sinusoidal torsion profile.
- the translational movement of the movable guide device in translation prints a substantially triangular profile in the optical fiber.
- the middle of the race corresponds to the equilibrium position of the optical fiber 4.
- the distance between, on the one hand, at least one point of contact between the movable guide device in translation and the optical fiber 4, and on the other hand, less than one point of contact between the optical fiber 4 and the anti-PMD pulley 1 is preferably less than or equal to the radius of the anti-PMD pulley 1.
- the guiding device movable in translation is disposed too far from the contact zone between the optical fiber 4 and the surface 10 of the anti-PMD pulley 1, then appear damping that smooth the torsion profile printed in the optical fiber 4 and which can go as far as transforming a profile, originally triangular, torsion into a sinusoidal torsion profile, which corresponds to a degradation of the torsion profile printed in the optical fiber 4.
- the guiding device Mobile in translation is therefore preferably placed as close as possible to the contact zone between the optical fiber 4 and the surface 10 of the anti-PMD pulley 1.
- the distance between, on the one hand, at least one point of contact between the translational guiding device and the optical fiber 4 and, on the other hand, at least one point of contact between the optical fiber 4 and the pulley 1 anti-PMD is less than or equal to half the radius of the anti-PMD pulley 1.
- the guide device movable in translation may comprise for example a V-shaped pulley whose axis of rotation is parallel to the rotational axis of rotation of the anti-PMD pulley 1.
- a guiding device has a significant inertia, as the oscillating pulley of the first prior art.
- the amplitude of the torsion torque increases, the amplitude of the movements of the pulleys increases and their inertia becomes more and more penalizing.
- guide fingers are used in place of the V-shaped pulley, these guide fingers having a much lower inertia than that of a pulley; the guiding fingers are also easier to clean than a V-groove narrow groove, then simply rotate the guide fingers around their axis of rotation, while a V-groove wide groove, easy to clean, will guide poorly the optical fiber 4.
- a parallel-faced pulley could also be considered, but it is unattractive insofar as it does not control the movement component of the optical fiber 4 in a parallel direction the diameter of said pulley parallel faces at its point of contact with the optical fiber 4.
- the guiding device movable in translation comprises at least two guiding fingers between which is intended to pass the optical fiber 4 during fiber drawing of the optical fiber 4.
- the movable guiding device in translation may be the device of Upstream guidance 2 or the downstream guidance device 3.
- the two upstream and downstream guidance devices 2 and 3 may also be translational guide devices.
- the guiding fingers are advantageously rotatable about axes distinct from each other.
- the axes of rotation 23 and 24 are parallel to each other but remain distinct from each other.
- the spacing of the guide fingers is large enough so as not to damage the coating of the optical fiber 4 during the fiberization of the optical fiber 4.
- this gap remains small enough to control the angular displacement between the plane of the optical fiber 4 and the plane PP of the anti-PMD pulley 1.
- the spacing between the guiding fingers is the free distance which separates the guiding fingers and in which the optical fiber 4 can pass.
- the guiding device movable in translation is preferably the downstream guiding device 3, that is to say the guiding device, located downstream of the anti-PMD pulley 1 with respect to the direction of travel dd2 of the optical fiber. 4 during the fiberizing of the optical fiber 4.
- Any vibrations caused by the translational movement of the guiding device 3 are generated further from other parts of the fiberizing tower located further upstream, where the optical fiber is more sensitive. , that in the case where the guide device movable in translation is the upstream guide device 2.
- said vibrations will be attenuated at the anti-PMD pulley 1. Avoiding or mitigating the propagation of vibrations towards the upstream parts of the fiberizing tower makes it possible in particular to improve the coating quality of the optical fiber 4.
- the anti-PMD system preferably also comprises an additional optical fiber guiding means, located downstream of the downstream guiding device 3 with respect to the direction of travel dd2 of the optical fiber 4 during fiberizing of the optical fiber 4, so as to absorb any vibrations.
- the movable guide device in translation may also be the upstream guide device 2, that is to say the guide device, located upstream of the anti-PMD pulley 1 with respect to the direction of travel dd1 of the optical fiber during fibering of the optical fiber.
- the anti-PMD system also comprises an additional optical fiber guiding means, located upstream of the upstream guiding device with respect to the direction of travel of the optical fiber 4 during fiberizing of the optical fiber 4, whatever the range of motion in translation of the upstream guide device 2, to prevent the propagation, to the upstream parts of the fiberizing tower, possible vibrations.
- the only guiding device movable in translation is the downstream guiding device 3, the upstream guiding device 2 being immobile in translation.
- the only guiding device movable in translation is the upstream guiding device 2, the downstream guiding device 3 being motionless in translation.
- the two upstream and downstream guide devices 3 are movable in translation.
- the two guiding devices are movable in translation preferentially in the same direction of translation dt. To increase the amplitude of the torsion torque applied to the optical fiber 4, the two guiding devices move in opposite directions to one another along said translation direction dt.
- the downstream guiding device 3 moves in the direction s2, and vice versa.
- the contact surface between the surface 10 of the anti-PMD pulley 1 and the part of the optical fiber 4 which is angularly offset with the plane PP of the anti-PMD pulley 1 is larger, which makes it possible, for a same amplitude of movement in translation, to double the torsion torque applied to the optical fiber 4.
- the anti-PMD pulley 1 is preferably a return pulley, that is to say that the travel directions of the optical fiber 4, dd1 upstream of the anti-PMD pulley 1 and dd2 downstream of the pulley 1 anti-PMD, are perpendicular to each other.
- the fiber-drawing tower generally comprises a deflection pulley in order to reduce the necessary height of the fiber-drawing tower.
- the anti-PMD pulley 1 can also be located downstream of the return pulley with respect to the direction of travel of the optical fiber 4 during the fiberizing of the optical fiber 4.
- the vibrations propagating towards the parts of the fiber-drawing tower situated upstream of the return pulley are further attenuated and the coating quality of the optical fiber 4 is further improved; the disadvantage is the need to add a pulley on the fiber drawing tower.
- the anti-PMD pulley 1 must of course have a width at its peripheral surface 10 which is sufficient to allow the excursions of the optical fiber 4 when it rolls on the surface 10.
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- Manufacturing & Machinery (AREA)
- Materials Engineering (AREA)
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- Optical Fibers, Optical Fiber Cores, And Optical Fiber Bundles (AREA)
- Guides For Winding Or Rewinding, Or Guides For Filamentary Materials (AREA)
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Abstract
Description
L'invention concerne le domaine des systèmes anti-PMD dont le but est de diminuer la PMD d'une fibre optique lors du procédé de fibrage. La PMD est la dispersion modale de polarisation (« polarization modal dispersion » en terminologie anglo-saxonne). La dispersion modale de polarisation est un inconvénient pour la fibre optique car elle entraîne une dégradation du signal se propageant dans la fibre optique. Cet inconvénient prend de plus en plus d'importance au fur et à mesure que les débits dans les réseaux de communication à fibres optiques augmentent.The invention relates to the field of anti-PMD systems whose purpose is to reduce the PMD of an optical fiber during the fiber drawing process. PMD is polarization modal dispersion ("polarization modal dispersion" in English terminology). The polarization mode dispersion is a disadvantage for the optical fiber because it causes a degradation of the signal propagating in the optical fiber. This disadvantage becomes more and more important as the rates in fiber optic communication networks increase.
Selon un premier art antérieur, il est connu d'utiliser un système anti-PMD appelé système SZ. Ce système est basé sur l'utilisation d'une poulie oscillante en rotation. Cette poulie oscillante est une poulie anti-PMD. Ce système est par exemple décrit dans le brevet européen EP 582405 incorporé ici par référence, ou encore dans le brevet européen EP 744636. Le système SZ est positionné à la base de la tour de fibrage, dans le plan de passage de la fibre optique laquelle fibre optique fait un coude au niveau de la poulie anti-PMD. Le plan de passage de la fibre optique est aussi appelé plan de fibrage. La poulie, en rotation autour de son axe de rotation, oscille également autour de l'axe vertical de fibrage lequel axe est son axe d'oscillation, et symétriquement par rapport au plan de fibrage. Des poulie en V situées avant la poulie oscillante et des doigts de guidage situés après la poulie oscillante permettent de guider la fibre optique dans le plan de fibrage. L'axe des poulies en V est immobile. L'ensemble constitué par les doigts de guidage est globalement immobile, c'est-à-dire que l'ensemble constitué par les doigts de guidage n'est ni en mouvement de translation ni en mouvement de rotation, ni en mouvement qui serait une combinaison de translation et de rotation. Les poulies en V n'ont pas non plus de mouvement de translation. Les oscillations de la poulie oscillante, alternativement de droite à gauche puis de gauche à droite, appliquent un couple de torsion sur la fibre optique qui est déjà recouverte de son revêtement secondaire. Un inconvénient de cet art antérieur est d'aboutir à des fibres optiques dont la PMD reste encore trop élevée à cause des rotations de la fibre optique sur la surface de la poulie oscillante qui sont insuffisamment contrôlées. En effet, soit lorsque l'angle entre le plan de la poulie oscillante et le plan de fibrage augmente, soit lorsque la fréquence d'oscillation de la poulie oscillante augmente, la position de la fibre optique qui roule sur la surface de la poulie oscillante n'est plus maîtrisée, car l'inertie de la fibre optique a tendance à la faire rester au centre de la poulie, au lieu de la maintenir dans le plan de fibrage de manière à augmenter l'angle entre le plan de la poulie oscillante et le plan de la fibre jusqu'à la valeur souhaitée. Cette tendance à rester sur place peut amener la fibre optique à glisser sur la surface de la poulie oscillante au lieu de rouler dessus, au niveau des extrémités de la course des oscillations de la poulie oscillante.According to a first prior art, it is known to use an anti-PMD system called SZ system. This system is based on the use of a rotating oscillating pulley. This oscillating pulley is an anti-PMD pulley. This system is for example described in the European Patent EP 582405 incorporated herein by reference, or in European Patent EP 744636. The SZ system is positioned at the base of the fiberizing tower, in the plane of passage of the optical fiber which Optical fiber makes an elbow at the anti-PMD pulley. The plane of passage of the optical fiber is also called fiber drawing plan. The pulley, in rotation about its axis of rotation, also oscillates around the vertical fibering axis, which axis is its axis of oscillation, and symmetrically with respect to the fiber drawing plane. V-pulley located before the oscillating pulley and guide fingers located after the oscillating pulley are used to guide the optical fiber in the fiber drawing plane. The axis of the V-shaped pulleys is stationary. The assembly constituted by the guide fingers is generally immobile, that is to say that the assembly constituted by the guide fingers is neither in translation movement nor in rotational movement, nor in motion which would be a combination of translation and rotation. V-pulleys also have no translational movement. Oscillations of the oscillating pulley, alternately from right to left then from left to right, apply a torsion torque on the optical fiber which is already covered with its secondary coating. A disadvantage of this prior art is to result in optical fibers whose PMD is still too high because rotations of the optical fiber on the surface of the oscillating pulley that are insufficiently controlled. Indeed, either when the angle between the plane of the oscillating pulley and the fibering plane increases, or when the oscillation frequency of the oscillating pulley increases, the position of the optical fiber which rolls on the surface of the oscillating pulley is no longer controlled because the inertia of the optical fiber tends to keep it in the center of the pulley, instead of maintaining it in the fiber plane so as to increase the angle between the plane of the oscillating pulley and the plane of the fiber up to the desired value. This tendency to remain in place may cause the optical fiber to slide on the surface of the oscillating pulley instead of rolling on, at the ends of the oscillating pulley oscillations stroke.
Selon un deuxième art antérieur, il est connu, par exemple du « Patent Abstract of Japan » JP 2000344539, d'utiliser une poulie mobile en translation comme poulie anti-PMD à la place de la poulie oscillante du premier art antérieur. Les moyens de guidage situés en amont et en aval de la poulie anti-PMD, n'ont pas de mouvement en translation. Ce deuxième art antérieur présente le même problème de contrôle insuffisant des rotations de la fibre optique sur la surface de la poulie anti-PMD à cause de l'inertie de la fibre optique. De plus, la poulie anti-PMD mobile en translation autour de son axe de rotation présente de plus l'inconvénient d'appliquer à la fibre optique une torsion décroissante avec la vitesse de fibrage pour une fréquence de translation donnée de la poulie anti-PMD, à moins de faire varier cette fréquence de translation, ce qui compliquerait nettement le système.According to a second prior art, it is known, for example from "Patent Abstract of Japan" JP 2000344539, to use a pulley movable in translation as an anti-PMD pulley in place of the oscillating pulley of the first prior art. The guide means located upstream and downstream of the anti-PMD pulley, have no movement in translation. This second prior art has the same problem of insufficient control of rotations of the optical fiber on the surface of the anti-PMD pulley because of the inertia of the optical fiber. In addition, the anti-PMD pulley mobile in translation about its axis of rotation has the further disadvantage of applying to the optical fiber a decreasing twist with the drawing speed for a given translation frequency of the anti-PMD pulley. unless this frequency of translation is varied, which would significantly complicate the system.
Selon un troisième art antérieur, il est connu d'utiliser deux poulies anti-PMD pour coincer la fibre optique entre elles et imposer l'angle entre plans de poulies et plan de fibrage, par exemple deux poulies mobiles en translation l'une par rapport à l'autre comme dans la demande de brevet américaine US2002/0026813, ou encore deux poulie oscillantes. Ce troisième art antérieur permet un contrôle adéquat de la rotation de la fibre optique à vitesses de fibrage modérées mais au prix d'inconvénients supplémentaires. Parmi ces inconvénients supplémentaires se trouvent, une mécanique compliquée et fragile du système de manière à coincer la fibre optique tout en essayant de ne pas trop l'endommager, ainsi qu'à vitesse élevée de fibrage, typiquement au-delà de 1000m/min, des problèmes soit de qualité de revêtement si la fibre optique est trop fortement coincée entre les poulies anti-PMD, soit de guidage de la fibre optique si celle-ci est trop faiblement coincée entre les poulies anti-PMD. Lesdits problèmes de guidage entraînent une diminution du temps de contact entre fibre optique et poulies anti-PMD, d'où une diminution de l'efficacité de rotation de la fibre optique sur les poulies anti-PMD, d'où une diminution du couple de torsion appliqué sur la fibre optique par les poulies anti-PMD, et par conséquent une valeur de PMD trop élevée sur la fibre optique finale, c'est-à-dire en fin de fibrage. Les problèmes de variation de diamètre de fibre optique sont très mal gérés par ce genre de système comprimant la fibre optique entre deux poulies anti-PMD, car lorsque le diamètre de la fibre optique varie, la force de compression est toujours ou bien trop élevée ou bien trop faible.According to a third prior art, it is known to use two anti-PMD pulleys to wedge the optical fiber between them and to impose the angle between the pulley planes and the fiber drawing plane, for example two pulleys that are movable in translation relative to one another. to the other as in the US2002 / 0026813 US patent application, or two oscillating pulley. This third prior art allows adequate control of the rotation of the optical fiber at fiber drawing speeds moderate but at the cost of additional inconveniences. Among these additional disadvantages are a complicated and fragile mechanism of the system so as to jam the optical fiber while trying not to damage it too, as well as at high fiber drawing speed, typically above 1000m / min, problems of coating quality if the optical fiber is too strongly wedged between the anti-PMD pulleys, or guiding the optical fiber if it is too weakly wedged between the anti-PMD pulleys. Said guiding problems result in a reduction in the contact time between the optical fiber and the anti-PMD pulleys, hence a reduction in the rotation efficiency of the optical fiber on the anti-PMD pulleys, hence a reduction in the torque of torsion applied on the optical fiber by the anti-PMD pulleys, and therefore a too high PMD value on the final optical fiber, that is to say at the end of fiber drawing. The problems of variation of optical fiber diameter are very poorly managed by this kind of system compressing the optical fiber between two anti-PMD pulleys, because when the diameter of the optical fiber varies, the compression force is always either too high or far too weak
L'invention propose un système anti-PMD amélioré, permettant à la fois, un bon contrôle de la rotation de la fibre optique sur la poulie anti-PMD obtenu par un meilleur guidage de la fibre optique au niveau de son décalage angulaire par rapport au plan de la poulie anti-PMD, une bonne qualité de revêtement de fibre optique obtenue par l'absence de compression excessive de la fibre optique, le système anti-PMD étant de plus relativement simple et robuste. Pour cela, la poulie anti-PMD a un axe de rotation fixe et un seul degré de liberté autour de cet axe qui est un degré de liberté en rotation autour de cet axe, tandis qu'au moins l'un des dispositifs de guidage est mobile en translation de manière à pouvoir faire varier l'angle entre le plan de fibrage et le plan de la poulie anti-PMD en maîtrisant la rotation effective de la fibre optique sur la surface de la poulie anti-PMD. Au contraire des premier et deuxième arts antérieurs, la rotation de la fibre optique sur la surface de la poulie anti-PMD est ainsi contrôlée et maîtrisée, car l'élément responsable de la variation de l'angle entre plan de fibrage et plan de poulie anti-PMD est un élément de guidage qui contrôle par conséquent mieux le décalage angulaire entre le plan de la poulie anti-PMD et le plan de fibrage de la fibre optique. Au lieu d'un guidage selon deux axes perpendiculaires comme dans le premier art antérieur utilisant une poulie oscillante, un guidage selon un seul axe est réalisé par le biais d'un mouvement en translation du dispositif de guidage, ce qui est plus simple. L'utilisation d'une seule poulie anti-PMD évite tous les problèmes de compression de la fibre optique du troisième art antérieur, tandis que la réduction des degrés de liberté de la poulie anti-PMD entraîne une simplification et une robustesse accrues du système. Par ailleurs, au contraire du deuxième art antérieur et d'une partie du troisième art antérieur, lesquels utilisent une poulie anti-PMD mobile en translation également, le couple de torsion, qui s'exprime en tours par mètre de fibre optique, appliqué à la fibre optique est indépendant de la vitesse de fibrage. Pour une fréquence d'oscillation constante, la vitesse de rotation moyenne de la fibre optique est constante quelle que soit la vitesse de fibrage. Par contre, le profil de rotation, c'est-à-dire la répartition spatiale et le sens de rotation le long de la fibre optique, va évoluer. Tandis que pour un système de poulie en translation comme selon le deuxième art antérieur, la vitesse de rotation moyenne diminue avec la vitesse de fibrage, et le profil de rotation varie également avec la vitesse de fibrage.The invention proposes an improved anti-PMD system, allowing at the same time a good control of the rotation of the optical fiber on the anti-PMD pulley obtained by a better guiding of the optical fiber at its angular offset with respect to the anti-PMD pulley plane, a good quality of optical fiber coating obtained by the absence of excessive compression of the optical fiber, the anti-PMD system being moreover relatively simple and robust. For this, the anti-PMD pulley has a fixed axis of rotation and a single degree of freedom around this axis which is a degree of freedom in rotation about this axis, while at least one of the guiding devices is movable in translation so as to be able to vary the angle between the fiber drawing plane and the plane of the anti-PMD pulley by controlling the effective rotation of the optical fiber on the surface of the anti-PMD pulley. Unlike the first and second prior arts, the rotation of the optical fiber on the surface of the anti-PMD pulley is thus controlled and controlled because the element responsible for the variation of the angle between the fiber plane and the plane of Anti-PMD pulley is a guide element which therefore better controls the angular offset between the plane of the anti-PMD pulley and the fibering plane of the optical fiber. Instead of a guide along two perpendicular axes as in the first prior art using an oscillating pulley, guidance along a single axis is achieved by means of a translational movement of the guide device, which is simpler. The use of a single anti-PMD pulley avoids all the compression problems of the optical fiber of the third prior art, while the reduction of the degrees of freedom of the anti-PMD pulley leads to an increased simplification and robustness of the system. Moreover, unlike the second prior art and a part of the third prior art, which use a non-translational anti-PMD pulley also in translation, the torsion torque, which is expressed in revolutions per meter of optical fiber, applied to the optical fiber is independent of the fiber drawing speed. For a constant oscillation frequency, the average rotation speed of the optical fiber is constant regardless of the fiber drawing speed. On the other hand, the rotation profile, that is to say the spatial distribution and the direction of rotation along the optical fiber, will evolve. While for a pulley system in translation as in the second prior art, the average speed of rotation decreases with the fiber drawing speed, and the rotation profile also varies with the fiber drawing speed.
Selon l'invention, il est prévu un système anti-PMD comprenant, une poulie anti-PMD sur laquelle une fibre optique est destinée à rouler et qui est rotative autour d'un axe de rotation, au moins deux dispositifs de guidage de fibre optique situés de part et d'autre de la poulie anti-PMD, caractérisé en ce que l'axe de rotation de la poulie anti-PMD est fixe, en ce que le seul degré de liberté de la poulie anti-PMD est la rotation autour de l'axe de rotation de la poulie anti-PMD, et en ce qu'au moins l'un des dispositifs de guidage est mobile en translation selon une direction de translation non orthogonale à l'axe de rotation de la poulie anti-PMD.According to the invention, there is provided an anti-PMD system comprising, an anti-PMD pulley on which an optical fiber is intended to roll and which is rotatable about an axis of rotation, at least two optical fiber guiding devices. located on either side of the anti-PMD pulley, characterized in that the axis of rotation of the anti-PMD pulley is fixed, in that the only degree of freedom of the anti-PMD pulley is the rotation around it of the axis of rotation of the anti-PMD pulley, and in that at least one of the guiding devices is movable in translation in a non-orthogonal direction of translation to the axis of rotation of the anti-PMD pulley. .
Selon l'invention, il est prévu de préférence un système anti-PMD dans lequel, lors du fibrage de la fibre optique, le dispositif de guidage mobile en translation décale angulairement la fibre optique par rapport à un plan perpendiculaire à l'axe de rotation de la poulie anti-PMD, et la poulie anti-PMD applique, alternativement dans le sens des aiguilles d'une montre et dans le sens inverse à celui des aiguilles d'une montre, un couple de torsion à la fibre optique de manière à diminuer sa PMD.According to the invention, an anti-PMD system is preferably provided in which, during the fiber-optic fiberization, the movable guiding device translation shifts the optical fiber angularly relative to a plane perpendicular to the axis of rotation of the anti-PMD pulley, and the anti-PMD pulley applies, alternately in the direction of clockwise and in the opposite direction to that clockwise, a torsion torque to the optical fiber so as to reduce its PMD.
L'invention sera mieux comprise et d'autres particularités et avantages apparaîtront à l'aide de la description ci-après et des dessins joints, donnés à titre d'exemples, où :
- la figure 1 représente schématiquement un exemple préférentiel de système anti-PMD selon l'invention.
- FIG. 1 schematically represents a preferred example of an anti-PMD system according to the invention.
Les différentes étapes de fabrication de la fibre optique lors du procédé de fibrage ont une influence importante sur les ovalités d'indice et de géométrie du coeur de la préforme et par conséquent de la fibre optique également, lesquelles ovalités sont l'une des causes d'une PMD importante. Or, les fibres optiques dont la PMD est trop importante ne peuvent pas être vendues car ladite PMD dégraderait de manière trop importante le signal optique transmis par ladite fibre optique. Lors du fibrage, la méthode utilisée pour réduire la PMD d'une fibre optique, consiste à faire tourner la fibre optique sur elle-même, alternativement dans un sens de rotation, par exemple le sens des aiguilles d'une montre, puis dans l'autre, par exemple le sens inverse à celui des aiguilles d'une montre. Le système anti-PMD, qui permet de vriller la fibre optique, situé à la base de la tour de fibrage, agit de préférence sur la fibre optique recouverte de ses deux revêtements. Le couple de torsion, appliqué à la fibre optique, est transmis jusqu'au cône de verre visqueux de la préforme, situé dans le four de fibrage, plusieurs mètres au-dessus du système anti-PMD. Le verre « mou » et vrillé qui est tiré vers le bas de la tour de fibrage par la traction du cabestan, se refroidit ensuite rapidement (c'est ce que l'on appelle la « trempe du verre »), ce qui fige dans le verre, la torsion exercée par le système anti-PMD. Dans une limite raisonnable, plus la fibre optique est vrillée alternativement dans un sens puis dans l'autre, plus la PMD de ladite fibre optique sera faible et mieux ce sera. La PMD liée à l'ovalité d'indice (ovalité d'indice de coeur dans le plan perpendiculaire à l'axe de transmission de la lumière) peut être corrigée par la torsion de la fibre optique, comme pour l'ovalité géométrique. Par contre, une PMD qui serait liée à un défaut dans le verre, ou à une variation d'indice dans l'axe longitudinal de la fibre optique, ne serait pas modifiée par le système anti-PMD.The various stages of fabrication of the optical fiber during the fiber drawing process have an important influence on the ovality of the index and geometry of the core of the preform and consequently also of the optical fiber, which ovalities are one of the causes of a significant PMD. However, optical fibers whose PMD is too large can not be sold because said PMD degrade too much the optical signal transmitted by said optical fiber. During fiberizing, the method used to reduce the PMD of an optical fiber consists of rotating the optical fiber on itself, alternatively in a direction of rotation, for example clockwise, and then in the direction of rotation. other, for example the opposite direction to that of the needles of a watch. The anti-PMD system, which makes it possible to twist the optical fiber, located at the base of the fiberizing tower, preferably acts on the optical fiber covered with its two coatings. The torsion torque, applied to the optical fiber, is transmitted to the viscous glass cone of the preform, located in the fiberizing furnace, several meters above the anti-PMD system. The "soft" and twisted glass that is pulled down from the fiber-drawing tower by pulling the capstan, then cools rapidly (this is called "glass tempering"), which freezes glass, the twist exerted by the anti-PMD system. Within a reasonable limit, the more the optical fiber is twisted alternately in one direction then in the other, the lower the PMD of said optical fiber will be and the better. The PMD linked to the index ovality (ovality of the index of the core in the plane perpendicular to the light transmission axis) can be corrected by the torsion of the optical fiber, as for the geometric ovality. On the other hand, a PMD which is linked to a defect in the glass, or to a variation of index along the longitudinal axis of the optical fiber, would not be modified by the anti-PMD system.
La figure 1 représente schématiquement un exemple préférentiel de système anti-PMD selon l'invention. La flèche sd montre le sens amont-aval de défilement de la fibre optique 4 lors du fibrage. Une poulie 1 anti-PMD est rotative autour d'un axe ar de rotation. Le plan PP perpendiculaire à l'axe ar est le plan de la poulie 1 anti-PMD. La surface périphérique 10 de la poulie 1 anti-PMD est la surface sur laquelle la fibre optique 4 est destinée à rouler. La poulie 1 anti-PMD a un rayon R. De part et d'autre de la poulie 1 anti-PMD, sont situés des dispositifs 2 et 3 de guidage.FIG. 1 schematically represents a preferred example of an anti-PMD system according to the invention. The arrow sd shows the upstream-downstream direction of travel of the
En amont de la poulie 1 anti-PMD, se trouve le dispositif 2 de guidage amont. Le dispositif 2 de guidage amont est mobile en translation suivant une direction de translation représentée par les flèches dt. Le dispositif 2 de guidage amont comprend deux doigts 21 et 22 de guidage entre lesquels passe la fibre optique 4. Afin de ne pas endommager la qualité du revêtement de la fibre optique 4, les deux doigts 21 et 22 de guidage sont mobiles en rotation respectivement autour des axes 23 et 24. Au niveau du dispositif 2 de guidage amont, la direction de défilement de la fibre optique 4 est représentée par la flèche dd 1.Upstream of the anti-PMD pulley 1 is the upstream guiding
En aval de la poulie 1 anti-PMD, se trouve le dispositif 3 de guidage aval. Le dispositif 3 de guidage aval est mobile en translation suivant une direction de translation représentée par les flèches dt. Le dispositif 3 de guidage aval comprend deux doigts 31 et 32 de guidage entre lesquels passe la fibre optique 4. Afin de ne pas endommager la qualité du revêtement de la fibre optique 4, les deux doigts 31 et 32 de guidage sont mobiles en rotation respectivement autour des axes 33 et 34. Au niveau du dispositif 3 de guidage aval, la direction de défilement de la fibre optique 4 est représentée par la flèche dd2.Downstream of the anti-PMD pulley 1 is the downstream guiding device 3. The downstream guiding device 3 is movable in translation in a translation direction represented by the arrows dt. The downstream guiding device 3 comprises two guiding
Le plan de fibrage PF est le plan formé par les directions dd1 et dd2.The fibering plane PF is the plane formed by the directions dd1 and dd2.
L'axe ar de rotation de la poulie 1 anti-PMD est fixe, c'est-à-dire qu'il est fixe par rapport à l'ensemble du système anti-PMD qui lui-même est fixe par rapport à la tour de fibrage au bas de laquelle se trouve le système anti-PMD. L'axe ar est fixe au contraire des arts antérieurs à poulie oscillante, où l'axe de rotation était mobile de manière à pouvoir osciller.The ar axis of rotation of the anti-PMD pulley 1 is fixed, that is to say that it is fixed relative to the entire anti-PMD system which itself is fixed relative to the tower at the bottom of which is the anti-PMD system. The axis ar is fixed in contrast to the prior art oscillating pulley, where the axis of rotation was movable so as to be able to oscillate.
Le seul degré de liberté de la poulie 1 anti-PMD est la rotation autour de l'axe ar de rotation de la poulie 1 anti-PMD. La poulie 1 anti-PMD n'a pas d'autre degré de liberté dans un référentiel par rapport à l'ensemble du système anti-PMD et donc par rapport à la tour de fibrage, parmi les six degrés de liberté traditionnels, à savoir trois degrés de liberté en rotation et trois degrés de liberté en translation, la poulie 1 anti-PMD ne possède qu'un seul degré de liberté qui est un degré de liberté en rotation autour de l'axe ar. La poulie 1 anti-PMD ne possède notamment aucun degré de liberté en translation.The only degree of freedom of the anti-PMD pulley 1 is the rotation about the axis of rotation of the anti-PMD pulley 1. The anti-PMD pulley 1 has no other degree of freedom in a reference system with respect to the entire anti-PMD system and therefore compared to the fiberizing tower, among the six traditional degrees of freedom, namely three degrees of freedom in rotation and three degrees of freedom in translation, the pulley 1 anti-PMD has only one degree of freedom which is a degree of freedom in rotation about the axis ar. The pulley 1 anti-PMD has in particular no degree of freedom in translation.
Au moins l'un des dispositifs de guidage 2 ou 3 est mobile en translation selon une direction de translation dt qui est non orthogonale à l'axe ar de rotation de la poulie 1 anti-PMD. Ainsi grâce au mouvement de translation dudit dispositif de guidage, un décalage angulaire peut être créé entre le plan de la fibre et le plan PP de la poulie 1 anti-PMD, ce qui n'aurait pas été possible si la direction dt avait été orthogonale à l'axe ar de rotation.At least one of the
De préférence, la direction de translation dt du dispositif de guidage mobile en translation 2 ou 3 est située dans un plan parallèle à la fois à l'axe ar de rotation de la poulie 1 anti-PMD et respectivement à la direction de défilement dd1 ou dd2 de la fibre optique respectivement au niveau dudit dispositif de guidage 2 ou 3 lors du fibrage de la fibre optique, selon le dispositif de guidage qui est mobile en translation. Ainsi, une composante du mouvement en translation qui serait selon une direction orthogonale à l'axe ar de rotation et à la fibre optique 4, inutile pour créer ledit décalage angulaire, est supprimée.Preferably, the translation direction dt of the translationally
De préférence, la direction de translation dt est parallèle à l'axe ar de rotation de la poulie 1 anti-PMD. Ainsi, une composante du mouvement en translation qui serait selon une direction parallèle à la fibre optique 4, inutile pour créer ledit décalage angulaire, est supprimée.Preferably, the translation direction dt is parallel to the rotation axis ar of the anti-PMD pulley 1. Thus, a component of the translational movement which would be in a direction parallel to the
Le dispositif de guidage 2 ou 3, qui est mobile en translation, se déplace en translation suivant la direction dt de translation, alternativement dans le sens s1 puis dans le sens s2, les extrémités de sa course étant avantageusement situées de part et d'autre de la position d'équilibre de la fibre optique 4, préférentiellement à égale distance de ladite position d'équilibre de la fibre optique 4 laquelle position d'équilibre correspond à la verticale de la tour de fibrage. Sur la figure 1, la fibre optique 4 est représentée à sa position d'équilibre.The guiding
Lors du fibrage de la fibre optique 4, le dispositif de guidage mobile en translation décale angulairement la fibre optique 4 par rapport à un plan perpendiculaire à l'axe ar de rotation de la poulie 1 anti-PMD, ce plan perpendiculaire étant le plan PP de la poulie 1 anti-PMD. Grâce à ce décalage angulaire, et par l'intermédiaire de la vitesse de défilement de la fibre optique 4 au niveau de la poulie 1 anti-PMD, ladite poulie 1 anti-PMD applique, par l'intermédiaire du contact entre la fibre optique 4 et la surface 10 de la poulie 1 anti-PMD, alternativement dans le sens des aiguilles d'une montre et dans le sens inverse à celui des aiguilles d'une montre, un couple de torsion à la fibre optique 4 de manière à diminuer la PMD de la fibre optique 4.During fiberizing of the
Avec une poulie oscillante comme dans le premier art antérieur, le profil de torsion imprimé dans la fibre optique 4 est un profil sinusoïdal de torsion. Un profil triangulaire de torsion est meilleur qu'un profil sinusoïdal de torsion, notamment pour les fibres optiques monomodes standard et pour les fibres optiques à compensation de dispersion chromatique. Pour imprimer un profil triangulaire de torsion dans la fibre optique, il faut une commande sensiblement en créneau. Pour réaliser cette commande préférentielle sensiblement en créneau, le mouvement en translation du dispositif de guidage mobile en translation est beaucoup plus lent aux extrémités de la course dudit mouvement qu'au milieu de la course dudit mouvement de manière à imprimer dans la fibre optique lors du fibrage plutôt un profil triangulaire de torsion qu'un profil sinusoïdal de torsion. Idéalement, le mouvement en translation du dispositif de guidage mobile en translation imprime un profil sensiblement triangulaire dans la fibre optique. Le milieu de course correspond à la position d'équilibre de la fibre optique 4.With an oscillating pulley as in the first prior art, the torsion profile printed in the
De manière à pouvoir mieux maîtriser le profil de torsion imprimé dans la fibre optique 4, la distance, entre d'une part au moins un point de contact entre le dispositif de guidage mobile en translation et la fibre optique 4 et d'autre part au moins un point de contact entre la fibre optique 4 et la poulie 1 anti-PMD, est de préférence inférieure ou égale au rayon de la poulie 1 anti-PMD. En effet, si le dispositif de guidage mobile en translation est disposé trop loin de la zone de contact entre la fibre optique 4 et la surface 10 de la poulie 1 anti-PMD, alors apparaissent des amortissements qui lissent le profil de torsion imprimé dans la fibre optique 4 et qui peuvent aller jusqu'à transformer un profil, à l'origine triangulaire, de torsion en un profil sinusoïdal de torsion, ce qui correspond à une dégradation du profil de torsion imprimé dans la fibre optique 4. Le dispositif de guidage mobile en translation est donc de préférence placé le plus près possible de la zone de contact entre la fibre optique 4 et la surface 10 de la poulie 1 anti-PMD. A cause de la présence de la poulie 1 anti-PMD elle-même, rapprocher le dispositif de guidage mobile en translation, par exemple les doigts de guidage, de la zone de contact entre la fibre optique 4 et la surface 10 de la poulie 1 anti-PMD, implique de diminuer leur taille pour éviter tout contact entre le dispositif de guidage mobile en translation et la poulie 1 anti-PMD. De préférence, la distance, entre d'une part au moins un point de contact entre le dispositif de guidage mobile en translation et la fibre optique 4 et d'autre part au moins un point de contact entre la fibre optique 4 et la poulie 1 anti-PMD, est inférieure ou égale à la moitié du rayon de la poulie 1 anti-PMD. Pour qu'un tel point de contact existe, il suffit en fait que le minorant de toutes les distances, entre d'une part au moins un point de contact entre le dispositif de guidage mobile en translation et la fibre optique 4 et d'autre part au moins un point de contact entre la fibre optique 4 et la poulie 1 anti-PMD, soit inférieur au rayon de la poulie 1 anti-PMD.In order to be able to better control the torsion profile printed in the
Le dispositif de guidage mobile en translation peut comprendre par exemple une poulie en V dont l'axe de rotation est parallèle à l'axe ar de rotation de la poulie 1 anti-PMD. Cependant, un tel dispositif de guidage présente une inertie importante, tout comme la poulie oscillante du premier art antérieur. Or, au fur et à mesure de l'augmentation de l'amplitude du couple de torsion, l'amplitude des mouvements des poulies augmente et leur inertie devient de plus en plus pénalisante. Afin de diminuer l'inertie du dispositif de guidage mobile en translation, des doigts de guidage sont utilisés à la place de la poulie en V, ces doigts de guidage présentant une inertie bien inférieure à celle d'une poulie ; les doigts de guidage sont de plus bien plus faciles à nettoyer qu'une poulie en V à gorge étroite, il suffit alors de faire tourner les doigts de guidage autour de leur axe de rotation, tandis qu'une poulie en V à gorge large, facile à nettoyer, guidera quant à elle mal la fibre optique 4. Une poulie à faces parallèles pourrait aussi être envisagée, mais elle est peu intéressante dans la mesure où elle ne maîtrise pas la composante de mouvement de la fibre optique 4 suivant une direction parallèle au diamètre de ladite poulie à faces parallèles au niveau de son point de contact avec la fibre optique 4. Par ailleurs, ce type de poulie pose des problèmes de nettoyage du fait de l'espace libre très faible existant entre ses deux faces parallèles. Donc, de préférence, le dispositif de guidage mobile en translation comprend au moins deux doigts de guidage entre lesquels est destinée à passer la fibre optique 4 lors du fibrage de la fibre optique 4. Le dispositif de guidage mobile en translation peut être le dispositif de guidage amont 2 ou le dispositif de guidage aval 3. Les deux dispositifs de guidage amont 2 et aval 3 peuvent aussi être des dispositifs de guidage mobiles en translation. Les doigts de guidage sont avantageusement mobiles en rotation autour d'axes distincts entre eux. Par exemple dans le dispositif de guidage amont 2, les axes de rotation 23 et 24 sont parallèles entre eux mais restent distincts entre eux. De préférence, l'écartement des doigts de guidage est suffisamment important pour ne pas endommager le revêtement de la fibre optique 4 lors du fibrage de la fibre optique 4. Toutefois, cet écartement reste suffisamment faible pour maîtriser le déplacement angulaire entre le plan de la fibre optique 4 et le plan PP de la poulie 1 anti-PMD. L'écartement entre doigts de guidage, non visible sur la figure 1, est la distance libre qui sépare les doigts de guidage et dans laquelle peut passer la fibre optique 4.The guide device movable in translation may comprise for example a V-shaped pulley whose axis of rotation is parallel to the rotational axis of rotation of the anti-PMD pulley 1. However, such a guiding device has a significant inertia, as the oscillating pulley of the first prior art. However, as the amplitude of the torsion torque increases, the amplitude of the movements of the pulleys increases and their inertia becomes more and more penalizing. In order to reduce the inertia of the movable guide device in translation, guide fingers are used in place of the V-shaped pulley, these guide fingers having a much lower inertia than that of a pulley; the guiding fingers are also easier to clean than a V-groove narrow groove, then simply rotate the guide fingers around their axis of rotation, while a V-groove wide groove, easy to clean, will guide poorly the
Le dispositif de guidage mobile en translation est de préférence le dispositif de guidage aval 3, c'est-à-dire le dispositif de guidage, situé en aval de la poulie 1 anti-PMD par rapport au sens de défilement dd2 de la fibre optique 4 lors du fibrage de la fibre optique 4. D'éventuelles vibrations provoquées par le mouvement de translation du dispositif de guidage 3 sont générés plus loin des autres parties de la tour de fibrage situées plus en amont, là où la fibre optique est plus sensible, que dans le cas où le dispositif de guidage mobile en translation est le dispositif de guidage amont 2. De plus, lesdites vibrations seront atténuées au niveau de la poulie 1 anti-PMD. Eviter ou atténuer la propagation de vibrations vers les parties amont de la tour de fibrage permet notamment d'améliorer la qualité de revêtement de la fibre optique 4. Dans le cas d'une amplitude importante des mouvements de translation du dispositif de guidage aval 3, le système anti-PMD comprend préférentiellement aussi un moyen de guidage supplémentaire de fibre optique, situé en aval du dispositif de guidage aval 3 par rapport au sens de défilement dd2 de la fibre optique 4 lors du fibrage de la fibre optique 4, de manière à absorber d'éventuelles vibrations.The guiding device movable in translation is preferably the downstream guiding device 3, that is to say the guiding device, located downstream of the anti-PMD pulley 1 with respect to the direction of travel dd2 of the optical fiber. 4 during the fiberizing of the
Le dispositif de guidage mobile en translation peut aussi être le dispositif de guidage amont 2, c'est-à-dire le dispositif de guidage, situé en amont de la poulie 1 anti-PMD par rapport au sens de défilement dd1 de la fibre optique lors du fibrage de la fibre optique. Dans ce cas, le système anti-PMD comprend aussi un moyen de guidage supplémentaire de fibre optique, situé en amont du dispositif de guidage amont par rapport au sens de défilement de la fibre optique 4 lors du fibrage de la fibre optique 4, quelque soit l'amplitude du mouvement en translation du dispositif de guidage amont 2, pour éviter la propagation, vers les parties amont de la tour de fibrage, d'éventuelles vibrations.The movable guide device in translation may also be the
Dans un mode préférentiel de réalisation, le seul dispositif de guidage mobile en translation est le dispositif de guidage aval 3, le dispositif de guidage amont 2 étant immobile en translation. Dans un autre mode de réalisation, le seul dispositif de guidage mobile en translation est le dispositif de guidage amont 2, le dispositif de guidage aval 3 étant immobile en translation. Dans encore un autre mode préférentiel de réalisation, les deux dispositifs de guidage amont 2 et aval 3 sont mobiles en translation. Dans ce dernier mode préférentiel de réalisation, les deux dispositifs de guidage sont mobiles en translation préférentiellement selon la même direction de translation dt. Pour augmenter l'amplitude du couple de torsion appliqué à la fibre optique 4, les deux dispositifs de guidage se déplacent en sens contraire l'un de l'autre le long de ladite direction de translation dt. Lorsque le dispositif de guidage amont 2 se déplace dans le sens s1, le dispositif de guidage aval 3 se déplace dans le sens s2, et vice-versa. Ainsi, la surface de contact entre la surface 10 de la poulie 1 anti-PMD et la partie de la fibre optique 4 qui est angulairement décalée avec le plan PP de la poulie 1 anti-PMD est plus importante, ce qui permet, pour une même amplitude de mouvement en translation, de doubler le couple de torsion appliqué à la fibre optique 4. Il est aussi possible de commander indépendamment l'un de l'autre les dispositifs de guidage amont 2 et aval 3, de manière à obtenir des formes de profils de torsion imprimées dans la fibre optique 4 qui soient plus aléatoires ou tout au moins apériodiques au contraire des profils triangulaires ou sinusoïdaux.In a preferred embodiment, the only guiding device movable in translation is the downstream guiding device 3, the
La poulie 1 anti-PMD est de préférence une poulie de renvoi, c'est-à-dire que les directions de défilement de la fibre optique 4, dd1 en amont de la poulie 1 anti-PMD et dd2 en aval de la poulie 1 anti-PMD, sont perpendiculaires entre elles. La tour de fibrage comprend généralement une poulie de renvoi afin de diminuer la hauteur nécessaire de la tour de fibrage. Mais la poulie 1 anti-PMD peut aussi être située en aval de la poulie de renvoi par rapport au sens de défilement de la fibre optique 4 lors du fibrage de la fibre optique 4. Dans ce dernier cas, les vibrations se propageant vers les parties de la tour de fibrage situées en amont de la poulie de renvoi sont encore plus atténuées et la qualité de revêtement de la fibre optique 4 est encore améliorée ; l'inconvénient est la nécessité de rajouter une poulie sur la tour de fibrage. La poulie 1 anti-PMD doit bien sûr présenter une largeur au niveau de sa surface périphérique 10 qui soit suffisante pour permettre les excursions de la fibre optique 4 lorsque celle-ci roule sur la surface 10.The anti-PMD pulley 1 is preferably a return pulley, that is to say that the travel directions of the
Dans un exemple numérique selon l'invention, pour une vitesse de fibrage de 600 m/min (mètres par minute) et pour une fréquence d'oscillation du mouvement de translation du dispositif de guidage aval 3 seul mobile en translation, le décalage angulaire entre plan PP de la poulie 1 anti-PMD et plan de la fibre optique 4 évoluait entre +13° et -13°, donnant alors dans la fibre optique 4 une de torsion appliquée valant environ 3 tours par mètre.In a numerical example according to the invention, for a drawing speed of 600 m / min (meters per minute) and for an oscillation frequency of the translational movement of the downstream guiding device 3 only mobile in translation, the angular offset between PP plane of the anti-PMD pulley 1 and plane of the
Claims (18)
caractérisé en ce que l'axe (ar) de rotation de la poulie (1) anti-PMD est fixe, en ce que le seul degré de liberté de la poulie (1) anti-PMD est la rotation autour de l'axe (ar) de rotation de la poulie (1) anti-PMD, et en ce qu'au moins l'un des dispositifs de guidage (2, 3) est mobile en translation selon une direction de translation (dt) non orthogonale à l'axe (ar) de rotation de la poulie (1) anti-PMD.Anti-PMD system comprising, an anti-PMD pulley (1) on which an optical fiber (4) is intended to roll and which is rotatable about an axis (ar) of rotation, at least two guiding devices (2, 3) of optical fibers located on either side of the anti-PMD pulley (1),
characterized in that the axis (ar) of rotation of the anti-PMD pulley (1) is fixed, in that the only degree of freedom of the anti-PMD pulley (1) is the rotation about the axis ( ar) of rotation of the anti-PMD pulley (1), and in that at least one of the guiding devices (2, 3) is movable in translation in a translation direction (dt) not orthogonal to the axis (ar) of rotation of the anti-PMD pulley (1).
caractérisé en ce que, lors du fibrage de la fibre optique (4), le dispositif de guidage (2, 3) mobile en translation décale angulairement la fibre optique (4) par rapport à un plan perpendiculaire (PP) à l'axe (ar) de rotation de la poulie (1) anti-PMD, et la poulie (1) anti-PMD applique, alternativement dans le sens des aiguilles d'une montre et dans le sens inverse à celui des aiguilles d'une montre, un couple de torsion à la fibre optique (4) de manière à diminuer sa PMD.Anti-PMD system according to claim 1,
characterized in that , during fiber-drawing of the optical fiber (4), the translational guiding device (2, 3) angularly shifts the optical fiber (4) relative to a perpendicular plane (PP) to the axis ( ar) rotation of the anti-PMD pulley (1), and the anti-PMD pulley (1) applies, alternately clockwise and counterclockwise, a torque to the optical fiber (4) so as to decrease its PMD.
caractérisé en ce que l'écartement des doigts de guidage (21 et 22, 31 et 32) est à la fois suffisamment important pour ne pas endommager le revêtement de la fibre optique (4) lors du fibrage de la fibre optique (4) et suffisamment faible pour maîtriser le déplacement angulaire entre le plan de la fibre optique (4) et le plan (PP) de la poulie (1) anti-PMD.Anti-PMD system according to one of Claims 7 to 8,
characterized in that the spacing of the guide fingers (21 and 22, 31 and 32) is both large enough not to damage the coating of the fiber optical fiber (4) during fiberizing of the optical fiber (4) and sufficiently weak to control the angular displacement between the plane of the optical fiber (4) and the plane (PP) of the anti-PMD pulley (1).
caractérisé en ce que le dispositif de guidage (2, 3) mobile en translation est une poulie en V dont l'axe de rotation est parallèle à l'axe (ar) de rotation de la poulie (1) anti-PMD.Anti-PMD system according to one of Claims 1 to 6,
characterized in that the guide device (2, 3) movable in translation is a V-shaped pulley whose axis of rotation is parallel to the axis (ar) of rotation of the anti-PMD pulley (1).
caractérisé en ce que le système anti-PMD comprend une poulie de renvoi, et en ce que la poulie (1) anti-PMD est située en aval de la poulie de renvoi par rapport au sens de défilement (dd2) de la fibre optique (4) lors du fibrage de la fibre optique (4).Anti-PMD system according to one of Claims 1 to 16,
characterized in that the anti-PMD system comprises a return pulley, and in that the anti-PMD pulley (1) is located downstream of the return pulley with respect to the direction of travel (dd2) of the optical fiber ( 4) during fiberizing of the optical fiber (4).
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
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FR0307591 | 2003-06-24 | ||
FR0307591A FR2856805B1 (en) | 2003-06-24 | 2003-06-24 | SYSTEM COATING THE MODAL POLARIZATION DISPERSION OF AN OPTICAL FIBER |
Publications (2)
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EP1491511A1 true EP1491511A1 (en) | 2004-12-29 |
EP1491511B1 EP1491511B1 (en) | 2008-03-19 |
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EP04291420A Expired - Lifetime EP1491511B1 (en) | 2003-06-24 | 2004-06-07 | Anti-PMD system for optical fibres |
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US (1) | US7209604B2 (en) |
EP (1) | EP1491511B1 (en) |
JP (1) | JP4689974B2 (en) |
CN (1) | CN100366558C (en) |
AT (1) | ATE389621T1 (en) |
DE (1) | DE602004012484T2 (en) |
DK (1) | DK1491511T3 (en) |
FR (1) | FR2856805B1 (en) |
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JP2006347785A (en) * | 2005-06-13 | 2006-12-28 | Shin Etsu Chem Co Ltd | Optical fiber drawing device and drawing method |
JP4823590B2 (en) * | 2005-06-30 | 2011-11-24 | コマツ産機株式会社 | Processing machine control device, control method, and foot stand |
US7693357B2 (en) * | 2008-07-14 | 2010-04-06 | Ciena Corporation | Methods and systems for eliminating deleterious polarization effects in an optical fiber dispersion compensation module |
DE102008050152B4 (en) | 2008-10-01 | 2013-05-23 | Claas Guss Gmbh | High-strength, ductile cast iron alloy with nodular graphite and process for its production |
CN103771699A (en) * | 2012-10-17 | 2014-05-07 | 富通集团有限公司 | Optical fiber wringing equipment |
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Publication number | Publication date |
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ATE389621T1 (en) | 2008-04-15 |
JP4689974B2 (en) | 2011-06-01 |
CN100366558C (en) | 2008-02-06 |
US20050018943A1 (en) | 2005-01-27 |
JP2005015331A (en) | 2005-01-20 |
DK1491511T3 (en) | 2008-07-07 |
DE602004012484T2 (en) | 2009-04-16 |
DE602004012484D1 (en) | 2008-04-30 |
FR2856805A1 (en) | 2004-12-31 |
EP1491511B1 (en) | 2008-03-19 |
FR2856805B1 (en) | 2005-10-28 |
CN1572742A (en) | 2005-02-02 |
US7209604B2 (en) | 2007-04-24 |
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